KR101436680B1 - Sealing arrangement in rotating control valve of pressure fluid-operated percussion device - Google Patents

Abstract

The present invention relates to a sealing arrangement of a rotary control valve of a pressure fluid-operated shock device in which a tool (5) can be movably mounted in the longitudinal direction of the impact device, (4) movably mounted to compress the tool (5) suddenly to generate stress pulses in the tool (3) and the tool (5) To the inlet and outlet channels 7 and 9 and to the working chamber 3 through the channel of the switch member to alternately guide the pressure fluid through the channel and thus away from the working chamber 3, A control valve 8 having a rotary switch member having a channel for connecting the switch members 7 and 9, Has at least one sealing ring (20) for the purpose of sealing the inlet channel (7). In the arrangement, the sealing ring is obliquely mounted on the surface of the switch member and the switch member side surface of the sealing ring is essentially the shape of the surface of the switch member.

Description

Technical Field [0001] The present invention relates to a sealing arrangement of a rotary control valve of a pressure fluid-operated shock device,

The present invention relates to a sealing arrangement of a rotary control valve of a pressure fluid-operated shock device in which a tool can be movably mounted longitudinally relative to the frame of the impactor, A transfer piston movably mounted in the axial direction of the tool for suddenly compressing the tool longitudinally by the pressure of the pressure fluid acting on the transfer piston for generating a stress pulse, and a working chamber having a control valve, The inlet and outlet channels to the control valve guide the pressure fluid to and from the impactor and the control valve is operable to alternately direct the pressure fluid through the channel to the working chamber, In order to discharge the fluid, the inlet and outlet channels with the switch member are connected Which extends toward the surface of the switch member for the purpose of sealing the inlet channel to the switch member under the pressure of the pressure fluid at the inlet channel of the pressure fluid at the switch member side end thereof And at least one sealing ring.

In the pressure fluid-operated impact device, the pressure fluid is transferred into and removed from the impact device through the transfer and discharge channels, respectively. These transfer and discharge channels are typically connected with a pressure fluid hose to supply pressure fluid into the transfer pump and pressure fluid container.

For impact work, the transfer and discharge of the pressure fluid of the impacting device is controlled by various control valves. The control valve may move in a straight line or rotate. Particularly in rotary valves, one practical problem is the sealing between the valve and the channel, which causes all gaps to leak, and eventually the leakage causes low working efficiency. The sealing is also too tight to increase the rotational resistance of the valve, thus wasting the power of the device and lowering the operating efficiency of the device.

US Patent 7 290 622 discloses that a separate sealing sleeve is used to seal the rotary control valve and the sealing sleeve is pushed against the surface of the control valve by the pressure of the pressure fluid leaving a gap between the sealing sleeve and the control valve The solution to the problem is described. Adjusting the supply pressure of the sealing sleeve to keep the friction as low as possible is difficult to implement to some extent, even though a separate sealing sleeve structure is useful by itself.

It is an object of the present invention to provide a seal ring which is reliably achieved and at the same time the friction between the sealing sleeve and the rotary valve is reduced prior to the friction without affecting the reliability of the seal ring, Thereby providing an arrangement.

The sealing arrangement of the present invention is characterized in that the sealing ring is mounted obliquely to the surface of the switch member in the direction of rotation of the switch member and the surface of the sealing ring sleeve on the switch member side is essentially the same as the shape of the surface of the switch member .

The idea of the present invention is that at the inlet channel of the pressure fluid at the switch member side end, the sealing ring sleeve is positioned obliquely to the direction of movement of the surface of the rotating switch member of the valve. The idea of the embodiment of the present invention is that the sealing ring is positioned at an angle so that the end of the switch-member side of the sealing sleeve is before the opposite end of the sealing ring in the direction of rotation of the switch member.

The solution of the invention is that when the pressure fluid channel is only partially open, in this case the pressure of the pressure fluid acts on the sealing ring from the switch member side of the control valve and pushes down the sealing ring, The friction slows the movement of the sealing ring, thus achieving that the sealing ring remains better in position against the surface of the switch member. An advantage of the embodiment of the present invention is that the friction between the switch member and the seal ring sleeve tends to move the seal ring sleeve by the switch member in the direction of movement of the switch member when the switch member of the control valve rotates, So that the sealing sleeve extends away from the switch member and thus tries to separate it from the surface of the switch member. In this state, the force and friction acting on the sealing sleeve is balanced, whereby the sealing sleeve presses against the switch member with significantly less force than a sealing ring perpendicular to the switch member.

The present invention will be described in more detail in the accompanying drawings.

1 is a schematic cross-sectional view of an impact device having a rotation control valve.
2 is a detailed view showing a schematic cross-sectional view of a control valve and a sealing ring.
3 is a detailed view showing a schematic sectional view of an embodiment of the present invention.
4 is a schematic cross-sectional view of another embodiment of the present invention.
5 is a schematic cross-sectional view of another embodiment of the present invention.

1 is a schematic cross-sectional view of a prior art impact device 1 having a frame 2 with a working chamber 3 inside the frame and a transfer piston 4 inside the working chamber 3. The transfer piston 4 is coaxial with the tool 5 and they can move in the axial direction so that at least when the stress pulse begins to be formed and during its formation the transfer piston 4 is moved directly or indirectly to the tool 5, Shank and indirectly through the known per se. On the side of the transfer piston 4 facing the tool there is a pressure surface facing the work chamber 3. The pressure fluid is directed from the pressure source, such as the pump 6, to the working chamber 3 through the control valve 8 along the inlet channel 7 to form a stress pulse. When the inlet channel 7 is a single channel or reaches the control valve, it can branch to several channels from which the pressure fluid flows simultaneously to the control valve. The control valve has a movable switch member 8a having at least one channel 8b, such as an opening or a groove, as shown in the figure. As the switch member 8a of the control valve 8 moves, the pressure fluid acts on the transfer piston 4 through the channel 8b and, correspondingly, when the switch member 8a continues to move, 4 is discharged through the discharge channel 9. The pressure of the pressurized fluid acting on the discharge channel 9, Stress pulses are formed when the pressure fluid pressure pushes the transfer piston 4 towards the tool 5 and compresses the tool 5 against the material being broken through. When the stress pulse travels in a manner known per se through a tip of the tool 5, such as a drill bit, to a crushed material such as a rock, the stress pulse breaks the material. The switch member of the control valve 8 prevents the pressure fluid from entering the impact device and when the pressure fluid acting on the transfer piston 4 is discharged through the outlet channel 9 to the pressure fluid container 10, The pulse is stopped and the transfer piston 4, which has been moved a short distance towards the tool 5, only a few millimeters, is allowed to return to its initial position. This is repeated when the switch member 8a of the valve 8 is moved and alternately switched so that the pressure acts on the transfer piston, thereby eventually allowing the pressure to be discharged, whereby when the switch member 8a continues to move , A series of successive stress pulses are formed.

During use of the impacting device, it is pushed towards the tool 5 and at the same time in a manner known per se, using the transfer force F towards the material to be broken. In order to return the transfer piston 4, a pressure medium can be supplied to the chamber 3a between the stress pulses if necessary, or the transfer piston can be supplied by a mechanical means such as a spring, or by a transfer force in the drilling direction Can be returned by pushing the impact device, whereby the transfer piston moves rearwardly relative to the impact device, i.e. to its initial position. The tool may be a component that is separate from or integral with the piston in a manner known per se.

In the case of Fig. 1, the control valve 8 has a switch member 8a which rotatably moves coaxially with the tool 5, and this member is connected to the tool 5 by a power transmission, schematically indicated by a broken line, Is rotated about its axis in the direction of arrow A by using an appropriate rotating mechanism. Alternatively, the switch member 8a is rotatably pivoted back and forth using an appropriate mechanism. The rotatably moving switch member can also be mounted to the frame 2 on the side of the working chamber 3 in other respects, for example. It is also possible to use the control valve in all cases with only one channel for guiding the pressure fluid so that the switch member 8a is moved towards and, correspondingly, from the working chamber. However, the switch member 8a of the control valve 8 preferably has several parallel channels.

1 also shows a control unit 12 which can be connected by a control channel or signal lines 13a and 13b to control the rotational speed of the control valve or the reciprocating speed of the control valve. This type of adjustment can be carried out by several different techniques known per se, for example, using the required parameters such as the drilling conditions, the hardness of the rock to be broken.

2 is a detailed cross-sectional view of a rotary control valve and sealing arrangement of the present invention. As an embodiment, the disk type rotation switch member 8a of the control valve that rotates in the direction indicated by the arrow A is shown. The switch member 8a has a channel 8b to allow pressure fluid through the sealing ring 20 and into the piston 7 of the impacting device. At the end of the switch member 8a ending at the switch member 8a, the inlet channel 7 of the pressure fluid has a sealing ring 20.

) 로 스페이스 (2a) 에 장착되어 스위치 부재의 운동의 방향을 향하여 스위치 부재로부터 멀어져서 경사지게 된다. 따라서, 스위치 부재 (8a) 측의 시일링 슬리브 (20) 의 단부는, 스위치 부재 (8a) 로부터 더 멀리 떨어져 있는 측의 시일링 슬리브 (20) 의 단부보다, 스위치 부재 (8a) 의 운동 방향에서 앞쪽에 있게 된다. 시일링 슬리브 (20) 는 프레임 (2) 에 형성되는 또는 그의 부분인 스페이스 (2a) 에서 슬리브의 길이방향으로 미끄러질 수 있게 장착되고, 시일링 슬리브 (20) 의 최외 단부에, 스페이스 (21) 를 폐쇄하고 프레임 (2) 에 정적으로 연결되는 플러그 (22) 가 있다. 플러그 (22) 는 관통 채널 (23) 을 가지며, 이를 통하여 압력 유체가 시일링 슬리브 (20) 내측으로 흐르는 것이 가능하며 시일링 슬리브 (20) 내측의 채널 (20a) 을 통하여 앞으로 나아간다. As shown in Fig. 2, the sealing ring 20 is inclined at an angle of inclination with respect to the switch member 8a

And is tilted away from the switch member toward the direction of movement of the switch member. The end portion of the sealing ring 20 on the side of the switch member 8a is positioned at a distance from the end of the sealing ring 20 on the side farther from the switch member 8a in the direction of movement of the switch member 8a It will be on the front. The sealing sleeve 20 is slidably mounted in the longitudinal direction of the sleeve in a space 2a formed in or a part of the frame 2 and is provided at the outermost end of the sealing ring 20 with a space 21 There is a plug 22 which is closed and which is statically connected to the frame 2. The plug 22 has a through channel 23 through which pressure fluid is allowed to flow inside the sealing sleeve 20 and is advanced through the channel 20a inside the sealing ring 20.

The sealing sleeve has a space 21 which is larger in cross section than the channel 20a for the plug 22 and has a pressure surface 20b on its switch member 8a side. The pressure p of the pressure fluid acts on the surface 20b and the pressure p of the pressure fluid pushes the sealing ring 20 toward the switch member 8a so that the sealing ring 20 And is pressed against the surface of the switch member 8a. The plug 22 is not absolutely necessary and only the sealing ring 20 is sufficient when the inlet channel of the frame and pressure fluid and the sealing ring 20 are suitably designed.

2, the channels 20a and 8b of the sealing ring 20 and the switch member 8a are not completely straight, but the pressure of the pressure fluid acting on the channel 8b of the switch member 8a Corresponding to the surface 20c of the sealing ring 20 facing the switch member 8a. This pushes the sealing ring 20 away from the surface of the switch member 8a. Pressure pulses act on the sealing sleeve 20, particularly when the pressure fluid channel 20a is opened into the channel 8b of the switch member, or when the connection therebetween is closed. In this state, the friction between the sealing ring 20 and the surface of the space 2a slows or prevents the movement of the sealing ring 20 away from the switch member 8a, (20) essentially remains against the surface of the switch member (8a).

There is also friction between the surface of the switch member 8a and the surface of the sealing ring 20 when the switch member 8a rotates in the direction of the arrow B and this causes the sealing ring to move in the direction of movement of the switch member 8a I try to push it. Because of the inclined position of the sealing sleeve 20, the sealing sleeve 20 is pressed against the wall of the space 2a of the frame 2, so that the effect of the frictional force is greater in the longitudinal direction of the sealing ring 20 And therefore can not be directly moved by the switch member 8a. As a result, the sealing sleeve 20 tends to move away from the switch member 8a in its longitudinal direction, and in this way pushes the frictional force and, correspondingly, the sealing ring 20 facing the switch member 8a The force provided by the pressure is balanced and the friction between the switch member 8a and the sealing ring and the power loss caused by the friction is greater than in a sealing ring perpendicular to the surface of the switch member 8a little.

3 is a detailed view showing a schematic sectional view of an embodiment of the present invention. Here, a separate pressure pocket 8c is formed in the switch member 8a to reduce wear and friction between the switch member 8a and the sealing ring 20.

The pressure pocket 8c is a recess formed in the switch member 8a in the area between the channels 8b on the surface of the switch member 8a on the side of the sealing ring 20. This pocket is similar to when the connection of the channel to the pressure fluid channel 20a through the sealing ring at the position of the channel 8b is open or closed when it moves and passes the position of the sealing sleeve 20 A pressure effect is produced on the bottom surface of the sealing sleeve 20, whereby the sealing ring 20 tends to move away from the switch member 8a. This reduces the friction between the switch member 8a and the sealing ring 20, and consequently also reduces power consumption and wear.

4 is a view showing still another embodiment of the present invention. This figure shows how the rotational friction of the control valve 8 and thus the power consumption can also be reduced from before.

The inlet channel 7 of the pressurized fluid to which the pressurized fluid is transferred to the switch member 8a is provided with a sealing ring 20 in the manner described above and the pressure p of the pressurized fluid naturally always acts on the side Lt; / RTI >

The other side of the switch member 8a is located on the working chamber 3 side of the transfer piston 4. Essential for the sealing is that the sealing ring must be ensured well at the inlet side of the pressure fluid, but this is not a very important factor on the working chamber side since this side is always connected to the working chamber 3. This results because the channel on the side of the working chamber is only momentarily pressurized, while the inlet side of the pressure fluid is always pressurized. Therefore, the switch member 8a of the control valve 8 has the gap 25 between the switch member 8a and the impact device frame on the side of the working chamber 3 where the thrust bearing 24 is fitted. The size of the gap can be adjusted, for example, by using a separate gap plate or ring 26 having an appropriate thickness between the frame 2 and the switch member 8a. The thrust bearing 24 is eventually always in the pressure fluid and thus obtains the lubrication and cooling of the thrust bearing from this pressure fluid. The switch member 8a is rotated in a manner known per se through an axis 27, for example, by a suitable rotary device such as a hydraulic or electric motor.

5 is a view showing still another embodiment of the present invention. Here, the inclination of the sealing ring 20 shown by the arrow A is opposite to the inclination shown in Figs. 2 to 4. In this embodiment, the effect of the pressure fluid on the sealing sleeve 20 is similar to the effect in the other figures, but there is no lightening effect of surface tilting in the direction of motion. Also, the X table A 'in the circle indicates that the direction of movement of the switch member 8a can traverse the plane of the figure or it can be anything between the arrow A and the X table A'. In this embodiment, likewise, the effects of friction and pressure between the walls of the space 2a and the sealing ring 20 are the same.

In the foregoing, the invention has been described in the specification and drawings as an example only and the invention is not limited in any way by the description. The different details of the embodiments may be implemented in different ways and they may also be combined with one another. Thus, the details of the different drawings, Figs. 1-5, may be combined with one another in different ways to obtain the actually required embodiments. The rotation of the switch member 8a of the control valve 8 can be carried out in any manner known per se in a mechanical, electrical, pneumatic or hydraulic manner. The cross section of the sealing sleeve can be a circle, an ellipse, an angled one, or the like. Similarly, the angle of inclination may be, for example, between 45 ° or 30 ° to 80 °. Instead of the plate-shaped switch member 8a, the switch member may be cylindrical, conical or spherical as long as the shape of the end portion of the sealing member corresponds to the shape of the surface of the switch member. There may also be more than one sealing member.

Claims (6)

As the impacting device, the tool 5 can be movably mounted in the longitudinal direction with respect to the frame of the impacting device,
The impact device comprises a working chamber (3) having a transfer piston (4) and a control valve (8)
The transfer piston 4 is movably mounted in the axial direction of the tool 5 in order to generate a stress pulse in the tool 5 to suddenly move the tool 5 in the longitudinal direction by the pressure of the pressure fluid acting on the transfer piston, Lt; / RTI >
The inlet and outlet channels (7, 9) are connected to the control valve (8) to direct the pressure fluid to and from the impact device,
The control valve 8 is provided with a switch member 8a and a channel 8b that are rotatably mounted to alternately direct the pressure fluid through the channel 8b to the working chamber 3, To connect the inlet and outlet channels (7, 9) with the switch member (8a) to discharge pressure fluid from the working chamber (3)
The end portion of the inlet channel 7 of the pressure fluid at the side of the switch member 8a is connected to the end of the switch member 8a under the pressure of the pressure fluid for the purpose of sealing the inlet channel 7 to the switch member 8a. A pressure fluid-operated shock device having at least one sealing ring (20) extending toward a surface,
In the sealing arrangement of the rotary control valve of the pressure fluid-operated shock device,
The sealing ring 20 is slantingly mounted on the surface of the switch member 8a in the rotating direction of the switch member 8a and the surface of the sealing ring 20 on the switch member 8a side is essentially inclined with respect to the surface of the switch member 8a, Is the same as the shape of the surface of the seal ring (8a). The sealing arrangement according to claim 1, characterized in that the angle of inclination of the sealing ring (20) is 45 °. The seal ring according to claim 1 or 2, wherein the end of the sealing ring (20) on the side of the switch member (8a) is positioned forward of the end opposite to the side of the sealing ring (20) . The endoscope according to claim 1 or 2, wherein an end of the sealing ring (20) away from the switch member (8a) is connected to the end of the sealing ring (20) in the rotational direction of the switch member Characterized in that the sealing arrangement is a pre-sealing arrangement. A sealing arrangement according to any one of the preceding claims, characterized in that the surface of the switch member (8a) between the channels (8b) has at least one recess passing through the position of the sealing ring (20) . The pressure ring according to claim 1 or 2, wherein the sealing ring (20) has a channel having a larger diameter than the channel on the side of the switch member (8a) on the side of the pressure fluid inlet channel so that a pressure surface is formed in the inlet direction of the pressure fluid And a thrust force acting on the sealing ring (20) in the direction of the switch member (8a) is generated.

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